Recently, micro-LEDs (light-emitting diode) have emerged by the tremendous development of different optoelectronic applications such as augmented reality (AR), flexible screens, virtual reality (VR), etc. and is thus considered as the future display technology of next generation. Although micro-LEDs possess advantages of low power consumption, long lifetime, and high contrast, they still have many obstacles to improve. One of the challenges of micro-LEDs is the sharply reduction of external quantum efficiency (EQE) as the luminance size gets smaller. As the ratio of surface volume to volume increases, the sidewall damage caused by Inductively Coupled Plasma - Reactive Ion Etching (ICP-RIE) becomes increasingly significant. In our study, we introduce a digital etching and N2 treatment technology with different treatment times compared to different mesa sizes to repair the sidewall damage. As a result, at 25 A/cm2 of injection current, as the size of micro-LEDs decreases from 50x50 µm² to 8x8 µm², the EQE shows a reduction of 33.6%. Likewise, with a further reduction in size from 50x50 µm² to 4x4 µm², the EQE decreases by 56.9%. Furthermore, the detection is subject to many limitations due to the reduction in the size of micro-LEDs. Here, we demonstrated mass detection methods to examine both luminance and radiation profiles by using harmless ITO-glass contact on micro-LED array. The mass detection consists of two stages. In the first stage, we perform a calibration equation to calibrate the luminance data from resistance variation on every single micro-LED by multi-variable regression analysis. In the second stage, we determine the defective or non-uniform micro-LEDs by constructing and comparing different 2-D Convolutional Neural Network (CNN) models to find the most optimized one for micro-LED detection. Our new solution achieves in more efficiency and accuracy way for detection with error down to only 8 % for luminance detection and 96.7 % accuracy, 96.29 % precious, and 99.45 % recall for radiation profile recognition.